KAUST researchers have discovered how sea anemones recycle nitrogen waste, allowing them to thrive in nutrient-poor ocean environments. The study used laser microdissection and single-cell RNA-sequencing to analyze tissue-specific gene expression in Aiptasia. They found that anemones distribute glucose received from symbionts across tissues to recycle nitrogen waste. Why it matters: This research enhances understanding of coral reef ecosystems and their resilience, which is particularly relevant for Red Sea biodiversity and Saudi Arabia's environmental efforts.
A KAUST study explains how corals control their symbiotic algae using nutrient competition, tracking carbon and nitrogen isotopes. The research shows that cnidarians limit nitrogen available to the algae, preventing overgrowth and maintaining a balanced symbiosis. This mechanism evolved independently in corals, sea anemones, and jellyfish. Why it matters: The findings have implications for coral reef restoration efforts like the KAUST Reefscape Restoration Initiative by disrupting traditional views of symbiosis.
A KAUST-led study tracked clownfish and anemones in the Red Sea from 2022-2024, finding that extreme heat caused anemone bleaching, followed by near-total clownfish death, and then anemone death. The heatwave saw accumulated thermal stress reach 22 degrees heating weeks, far exceeding the threshold for coral bleaching. The research highlights heat risks faced by non-coral reef organisms and the need for taxon-specific thresholds to predict risks to reef symbiotic relationships. Why it matters: The Red Sea is a bellwether for climate change impacts on marine ecosystems, and this study underscores the urgency of conservation efforts like KAUST's Coral Restoration Initiative.
This is an announcement from KAUST about global coral bleaching. The announcement references King Abdullah bin Abdulaziz Al Saud. Why it matters: This indicates KAUST's involvement in research related to climate change and marine ecosystems.
KAUST researchers are studying corals in the Red Sea and Arabian Gulf that are more tolerant of high temperatures. They are mating corals from different parts of the world, assuming that the offspring will be more heat-resistant. Using a commercial coral spawning system, the researchers can time coral spawning to cross colonies that would not naturally cross. Why it matters: This research aims to identify genes responsible for temperature resilience and use selective breeding to increase coral resilience in the face of rising ocean temperatures.
Researchers from KAUST, JCU, and UTS discovered dozens of new coral species on the Great Barrier Reef during a 21-day expedition. The team found that the biodiversity of some coral groups is up to three times higher than previously thought. One hard coral species, Acropora hyacinthus, may actually be five different species. Why it matters: This discovery enhances the understanding of coral diversity and distribution, which is crucial for the conservation and management of Australia's World Heritage site.
KAUST researchers have conducted the first measurements of deep-sea corals in the Red Sea. They retrieved specimens of three different species at depths of 300-750 meters and temperatures exceeding 20 degrees Celsius. This discovery challenges the existing understanding that deep-sea corals are exclusive to cold-water environments. Why it matters: The research expands known ecosystem boundaries for deep-sea corals and demonstrates their resilience in warm, nutrient-poor waters, offering new insights into marine biodiversity and adaptation.
A team from KAUST attended the 9th International Symbiosis Society Congress in Oregon, U.S. in July. Hagen Gegner, a KAUST Ph.D. student, presented work on the role of high salinity in the thermotolerance of corals. He reflected on the pros and cons of presenting unpublished research, balancing transparency with potential exposure of sensitive findings. Why it matters: The participation of KAUST researchers in this international congress highlights the university's focus on marine biology and symbiosis, fostering collaboration and knowledge sharing in a competitive scientific field.